U.S. patent number 3,639,890 [Application Number 05/001,662] was granted by the patent office on 1972-02-01 for locking connector assembly.
This patent grant is currently assigned to The Bendix Corporation. Invention is credited to George M. Hubbard, William P. Stevens, William D. Wagner.
United States Patent |
3,639,890 |
Stevens , et al. |
February 1, 1972 |
LOCKING CONNECTOR ASSEMBLY
Abstract
An electrical connector assembly for use between a cable and
stationary device, the improvement being in the locking mechanism
of the connectors.
Inventors: |
Stevens; William P. (Franklin,
IN), Hubbard; George M. (Franklin, IN), Wagner; William
D. (Franklin, IN) |
Assignee: |
The Bendix Corporation
(N/A)
|
Family
ID: |
21697192 |
Appl.
No.: |
05/001,662 |
Filed: |
June 9, 1970 |
Current U.S.
Class: |
439/352; 285/921;
285/319 |
Current CPC
Class: |
H01R
13/6277 (20130101); Y10S 285/921 (20130101) |
Current International
Class: |
H01R
13/627 (20060101); H01r 013/54 () |
Field of
Search: |
;339/45,46,74-79,91
;285/319,DIG.22 ;287/119 |
References Cited
[Referenced By]
U.S. Patent Documents
Primary Examiner: McGlynn; Joseph H.
Claims
We claim:
1. A connector locking means for a first connector having a
housing, insulation, and contact pins; and a second connector
having a cable clamp, insulation, contact pins, and body,
comprising:
an undercut in said housing of said first connector;
a slidable sleeve around said body of said second connector, said
slidable sleeve having tines with a ridge for seating in said
undercut; and
a wedging surface on said body of said second connector to retain
said ridge in said undercut;
said wedging surface, said undercut, and said ridge being
beveled;
said tines being forced inwardly by a leading slope on said tines
and ridge when said first and second connectors are pushed
together;
said undercut and ridge being matchingly sloped on the rearward
edge of said ridge os that when said ridge is seated in said
undercut the two matchingly sloped surfaces are flat against one
another; said matching slope causing interference which forces said
sleeve to slide along said second connector when force is applied
to separate the two connectors unless said ridge has first been
unseated by a pull on said sleeve;
said wedging surface having a lessor angle with respect to the
longitudinal axis of said connectors than the angle of said
matching slopes, the sleeve moving along said second connector
until said tines contact said wedging surface upon attempted
separation other than pulling on said slidable sleeve thereby
forcing said ridge to remain seated in said undercut and stopping
the separation of the connectors;
the mating end of said body being of greater diameter than said
sleeve, the cable end of said body having an extension that is bent
outwardly to form a flange which secures a retaining nut, said
retaining nut holding said cable clamp to said second connection,
said retaining nut providing a stop for said slidable sleeve.
Description
BACKGROUND OF THE INVENTION
Electrical connectors provide the normal means for communication
between instruments and associated circuit devices. If
communication or connection is lost for only a few seconds, some
very critical information may not be received. To reduce the human
error of accidentally knocking or shaking a connector loose,
previous connector assemblies have employed some type of locking
means. One common type of locking means was a threaded connection
whereby the outer shell of the cable connector was screwed on the
stationary connector. Though this was satisfactory once connected,
it did not have the ease of connection needed for equipment that
may be connected and disconnected a number of times, and yet remain
securely locked once connected.
Another common locking device is a pin and camming surface whereby
the stationary connector has one or more pins located on its outer
shell, and the cable connector has a slot in its shell to match
each pin of the stationary connector. When the connectors are
mated, the cable connector shell is twisted so that the pin moves
along the slot in a camming action to draw the two connectors
securely together. At the end of the slot is located a groove
whereby the pin may seat to lock the two connectors in a mating
position. During normal connection of cables, it is very common
that the pin may not be securely seated in the groove. Unless the
pin is securely seated in the groove, the cable connector shell may
twist slightly from vibration or cable movement causing the pin to
no longer be located over the groove. Therefore, if a sudden pull
or jerk was accidentally exerted on the cable, the two connectors
may pull apart.
Attempts to minimize, if not eliminate, the human factor of
accidental disconnections have been numerous. The present invention
represents a new locking device over the previous locking
mechanisms shown. It has ease of operation, simplicity of design,
and high reliability not present in the prior art.
SUMMARY OF THE INVENTION
It is an object of this invention to provide a connector assembly
with a better locking mechanism.
It is a further object of this invention to provide a connector
assembly that may be easily connected and disconnected, but is very
difficult to accidentally pull loose.
It is a still further object of this invention provide a connector
assembly locking mechanism whereby a ridge of a locking sleeve of
the cable connector is pressed into an undercut groove of the
housing of the stationary connector to provide a retaining force
when the two connectors are mated together; but after being mated,
if a pull is exerted on the cable, a wedge surface of the cable
connector will provide an outward force on the locking sleeve to
securely lock the ridge in the groove so that the connectors can
only be disconnected by physically gripping the sleeve and sliding
it along the connector assembly to remove the wedging action and
retaining force.
BRIEF DESCRIPTION OF THE DRAWINGS
The invention will be more fully understood by the following
detailed description when taken together with the accompanying
drawings.
FIG. 1 is a longitudinal sectional view of a cable connector
assembly with a cable connected thereto.
FIG. 2 is a partially exploded view of the structure shown in FIG.
1.
FIG. 3 is a partial sectional view of the structure of FIG. 1,
showing the parts enlarged to better illustrate the invention.
DETAILED DESCRIPTION OF THE INVENTION
With reference to the accompanying FIGS., there is shown in FIG. 1
a sectional view of two connectors mated together with the
stationary connector being designated generally by reference
numeral 10 and the cable connector being designated generally by
reference numeral 12. The stationary connector consists generally
of a housing 14 for containing the male connector pin 18 which is
surrounded by insulation 16. A guide 20 helps position the cable
connector 12 so that it will be easier to assemble the two
connectors 10 and 12.
The cable connector consists generally of a female contact 22
surrounded by insulation 24 contained within The body 26. The
center part of the body 26 is encircled by a freely rotating
locking sleeve 28. A retaining nut 30 pulls the cable nut 32
against the clamp 34 to hold the cable 36 in rigid position. The
clamp 34 is separated from the contact 22 by an insulating washer
38.
The cable 36 is prepared for the connector 12 by removing a portion
of the covering 40 and shield 42, and a smaller portion of the
insulation 44 whereby the wire 46 can be inserted into the
connector contact 22 with the insulation 44 abutting the contact 22
and the covering 40 and shield 42 being forced against the clamp
34. To assemble the connector first put the cable nut 32 on the
cable 36 and then slide the clamp 34 under covering 40 and shield
44. Put the insulating washer 38 over the cable insulation 44 and
against the clamp 34 before inserting the wire 46 in the contact
22. Upon inserting the wire 46 in the contact 22, solder is applied
through an opening 48 to the cavity 50 into which the wire 46 was
inserted. Contact 22 is then inserted into the body assembly 51
(shown in FIG. 2) with a shoulder 52 of the contact 22 abutting a
shoulder 54 of the insulation 24. All the subcomponents shown in
FIG. 2 are securely fastened into place by screwing the retaining
nut 30 over the cable nut 32. It is important that the cable nut 32
remain stationary with respect to the cable 36 and that the
retaining nut 30 be turned, otherwise the square cut edges 56 of
the cable nut 32 will break the cable cover 40 and/or shield 42
when forcing them against the clamp's cone-shaped section 58. The
insulating washer 38 is designed to insulate the contact 22 from
the clamp 34 which is pressed against the outwardly protruding
flange 60 of the body 26.
The body 26 and insulation 24 are joined together by inserting the
insulation 24 into the body 26 and crimping them together at the
slotted portion 62 of the body. The locking sleeve 28 is slid over
the body 26 and the retaining nut 30 is butted against the
shoulders 64 of the body 26 in the position as shown. The end of
the body 26 inside the retaining nut is bent outward to form a
flange 60 which holds the body assembly 51 together.
The stationary connector 10 is, for the most part, a standard plug
receptacle. The pin 18 is embedded in the insulation 16 with point
66 electrically mating the spring pins 68 of contact 22. The lead
portions 70 and 72 of point 66 and spring pins 68, respectively,
are conically shaped to provide an easier mating connection. The
insulator 16 has a forward cylinder portion 74 to protect the point
66 and ensure the necessary electrical insulation. Shoulder 76 of
the insulation 16 butts shoulder 78 of the guide 20 with the flange
80 of the housing holding the connector 10 together. The guide 20
is physically attached to the housing 14 by some type of bonding.
The forward portion 82 of the guide 20 is arcuate to conform to
beveled rim 84 of the extension 86 by body 26. The arcuate shape 82
and beveled rim 84 provide an easy mating of the two connectors 10
and 12. The housing 14 is screwed into a chassis or bolted to a
chassis by means of threads 88 with the flange 90 pressing against
the panel surface.
Referring to the enlarged sectional view of FIG. 3, the locking
sleeve 28 has tines 92 extending toward the left of connector 12.
Each of the tines 92 have outwardly extending ridges 94 with two
oppositely beveled surfaces 96 and 98. The inside left portion 93
of the tine 92 is arcuate. The housing 14 of connector 10 has
undercut 100 into which the ridge 94 of the tines 92 will seat. The
undercut 100 is beveled so that surface 102 matches the
correspondingly beveled surface 96 in the ridge 94. Beveled surface
98 of the ridge 94 facilitates assembly of the cable connector 12
to the stationary connector 10. It is not necessary that beveled
surface 98 of the ridge 94 have a corresponding cut as does beveled
surface 104 in the housing 14.
The locking of the two connectors 10 and 12 occurs in the following
manner. When cable connector 12 is pushed into stationary connector
10, the tines 92 are forced inwardly by beveled surface 98 sliding
along the beveled surface 106. Once the ridge 94 reaches the
undercut 100, the tines 92 spring outwardly. The outward force of
the tines 92 securely seats the ridge 94 in the undercut 100.
Thereafter, if a pull or jerk is exerted on the cable 36, the
beveled surface 96 of the ridge 94 will press against the beveled
surface 102 of the housing 14. This interference between the
corresponding beveled surfaces 96 and 102 causes the locking sleeve
28 to slide along the moving connector 12 until the wedging surface
108 of the body 26 engages the arcuate portion 93 of the tines 92.
The wedging surface 108 tends to force the tines 92 outwardly so
that the ridge 94 cannot unseat from the undercut 100. This wedging
action of surface 108 stops the moving of connector 12 within the
sleeve 28 because the body 26 cannot pass through the tines 92
which have a smaller internal circumference than the external
portion of body 26. Since the tines 92 are secured in the undercut
100 of connector 10 and connector 12 is secured to the lines 92;
therefore cable connector 12 is secured to stationary connector 10.
The greater the force exerted on the cable 36 the tighter the wedge
becomes. After the ridge 94 has been seated in the undercut 100,
the only way the two connectors 10 and 12 can be disconnected is by
pulling the locking sleeve 28 toward the retainer nut 30 to remove
the interference between surfaces 96 and 102. Due to the fact that
the bevel angle of surface 96 is greater with respect to the
longitudinal axis of the connectors than the bevel angle of wedging
surface 108, the connector 12 (excluding the locking sleeve 28) may
have to move to the left a slight amount if the wedging surface 108
is against the arcuate portion 93. If no pulling force is being
exerted on the cable 36, the force of the pull on the locking
sleeve 28 will slide the arcuate portion 93 along the wedging
surface 108 thereby moving the connector 12 slightly to the left
which allows the locking sleeve 28 to move to the right and depress
the tines 92 inside the housing 14. After the interference between
surfaces 96 and 102 has been removed, the connectors 10 and 12 are
free to separate. Upon separation, the tines 92 spring outward into
their normal position.
From the foregoing it may be seen that applicants have invented a
novel mechanism for locking two connectors into their mating
portions. Though the present locking mechanism is shown in
conjunction with a particular type of stationary connector 10 and a
particular type of cable connector 12, it may be used in other
mating connectors. There is no limitation on the type of cable
being connected. A coaxial cable, multiconductor cable, or any
other type of cable could use the locking mechanism as described in
this disclosure or some variation thereof.
* * * * *